Machine for automatically measuring and taping cartons



July 24, 1962 c. D. KEELY ET AL MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS A LI at: 89w

ZOCIUMw Filed Nov. 14. 1960 A TOENEVS July 24, 1962 c. D. KEELY ET AL 3,045,402

MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheets-Sheet 2 I sac-now 2 LITE. SECTION 1 {I INVENTORS w CLIFFORD D. KEELV BY RFwMoNo J Bmspezv a? fauna/s n-r oewevs 14 Sheets$heet 3 C. D. KEELY ET AL July 24, 1962 MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed NOV. 14. 1960 ATTORNEYS ma v T Q15 i. {L i i Q2. QMQ QR $0 $3.

, M. ZOTFUww N ZOCIUMW July 24, 1962 c. D. KEELY ET AL MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheets-Sheet 4 w U mi 5 N v m M WDJ. r M i T mm 9 Y A ma QM WNV @N\ B T 0 x r D wk. Nfi F m m .ww vm/ w 2? a o m fi m 75 0 QQ\.\ n8 N z I m 0 zorrumm m ZoEbum wZEJoh July 24, 1962 c. D. KEELY ET AL 3,045,402

MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheds-Sheet 5 INVENTORS I48 760% RAYMOND JIBmsusv CLIFFORD D KEELI' r QZTOENEVS July 24, 1962 C. D. KEELY ET AL MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed NOV. 14. 1960 14 Sheets-Sheet 6 l ;L.I

T515. 374a fi 368a. 366a 0 332 2 Q2 INVENTORS CLIFFORD D. KEELY RAYMOND J. BHISLEH July 24, 1962 c. D. KEELY ET AL 3,045,402

MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheets-Sheet 8 INVENTORS CLIFFORD D. KEELY EHYMOND J. BFHSLEY 'eT-r ENEYS July 24, 1962 c. D. KEELY ET AL 3,045,402

MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheets-Sheet 9 Tifi.ll.

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0 a 656 INVENTORS CLIFFORD D. KEELY Revmouo J. Bmsuav QTTOENEVS July 24, 1962 c. D. KEELY ET AL MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS 14 Sheets-Sheet 10 Filed NOV. 14. 1960 wzjcmm was. 0 29.5mm

UZ NDWUZ P ZOTPUUw INVENTORS D. KEELH BYRHYMOND J. Bmsuzv CLIFF-OED 14 Sheets-Sheet 11 c. D. KEELY ET AL INVENTORS CLIFFORD D. KEELV RHYMOND J. Bmsuza M flu);

QTTOENEVS MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 July 24, 1962 July 24, 1962 c. D. KEE LY ET AL 3,045,402

MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS Filed Nov. 14. 1960 14 Sheets-Sheet 12 RAYMOND J. BRISLEY m aw QTTO ENEYS July 24, 1962 c. D. KEELY ET AL MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS 14 Sheets-Sheet 13 Filed Nov. 14. 1960 ZOFrUuQ $25 13. 4 UZNSflcmi INVENTORS CLIFFORD D. KEELV RnvMoND .J. BHISLEY n-r oervgvs MACHINE FOR AUTOMATICALLY MEASURING AND TAPING CARTONS July 24,1962 c. D. KEELY ET AL l4 Sheets-Sheet 14 Filed Nov. 14. 1960 Q umv wag INVENTORS CUFF-OED D KEELH' Rl-WMOND J. Bmsuzv BY QTTOENEY This invention relates to automatic carton taping machines having the novel characteristic of being self adaptable to the dimensions of cartons of widely varying widths, heights, and lengths.

It is now familiar practice to provide a car-ton taping machine having side guides adapted for ready adjustment to the widths of cartons throughout a wide range, overhead tape applying mechanism adapted for ready adjustment to the varying heights of cartons throughout a wide range, and tape feeding, cutting and pressing mechanism adapted to furnish and apply tape of appropriate lengths to the tops, or to the tops and bottoms of cartons of various lengths.

In these prior machines it has been necessary for an operator to adjust the side guides to the known width of a particular group of cartons, and to adjust the overhead tape applying mechanism and other associated mechanisms in accordance with the known height of the particular group of cartons. These adjustments have not only required human intervention, but they have consumed so much make-ready time as to make operation upon cartons which may vary in dimensions individually from cart-on to carton, economically impractical.

It is a primary object of the present invention to provide a fully automatic machine for taping cartons of widely varying dimensions.

It is a feature that during the processing of a car-ton, side guides are automatically moved outward to positions for clearing a carton of maximum accept-able width, and overhead mechanism is automatically moved upward for clearing a carton of maximum acceptable height, so that any carton within the size range of the machine may enter a first or measuring section of the machine. When this has occurred and a carton has been so accepted, the side guides located in the measuring section are automatically moved inward to center and align the carton, if necessary, and to assume guiding positions determined by the width of the particular carton for guiding the carton as it travels forward out of the measuring section. At the same time the overhead mechanism of the measuring section is moved downward automatically to an appropriate level determined by the carton itself.

Three illustrative embodiments of the invention are disclosed herein. In each of these embodiments the leading and trailing top flaps are folded down in the measuring section. in each of these embodiments the carton is detained in the measuring section until an over head mechanism provided in a next following section of the machine has been set in response to the height measurement effected in the first section, at the level which is appropriate to the height of the carton.

In one embodiment the second section is a side flap folding section in which the vertically adjustable overhead mechanism consists of automatically acting side flap folding instrumentalities. When the carton has moved into the second section far enough to clear the first, the side guiding and height measuring mechanisms of the first or measuring section move out and up, respectively, and a fresh carton may then be admitted to the measuring section. 7

Having reference to the first embodiment of the invention, the carton admitted to the side flap folding section ice adjustment to the height setting of the preceding section,

In the further embodiments, side flap folding instrumentalities are included in the first or measuring section and the taping section becomes the second section of the machine. The same principles of coordination between sections is retained as in the first embodiment, but the machine is simplified, and is made more compact.

In each embodiment the overhead taping instrumem tali-ties are desirably duplicated below, so that both the top and bottom of a filled carton may be automatically taped simultaneously.

It is :an important feature that in certain forms of the invention referred to above the mechanism is adapted to be converted back and forth by the mere flip of a switch between operation on the basis of causing each box to be automaticaliy individually measured, and advanced interruptedly as described above, and operation on the faster basis with cartons of uniform height and width, of eliminating individual measurement and of either eliminating or greatiy reducing interruption of advance.

Other objects and advantages will hereinafter appear.

In the drawing forming part of this specification,

FIGURE 1 is a perspective view of a first practical and advantageous illustrative machine which embodies features of the invention, as seen from one side of the machine at the introductory end thereof;

FIGURES 2 and 3 are complementary, horizontal, section-al views which jointly illustrate the machine from end to end;

FIGURE 4 is a view in side elevation of the machine, showing principally the frame work and the frame structure of the several sections including the elevators;

FIGURE 5 is a fragmentary view in end elevation, looking into the introductory end of the machine;

FIGURE 6 is a fragmentary view in side elevation of the mechanism illustrated in FIGURE 5;

FIGURE 7 is a detail View in horizontal section of one of a pair of side feeler arms through which the inward adjustment of the side guides is controlled;

FIGURE 8 is a partly electrical, partly mechanical view of roll-down mechanism employed in the taping section, and electrical control means therefor;

FIGURE 9 is a fragmentary plan view illustrating a portion of the side flap folding section and particularly the folding belts thereof;

FIGURE 10 is a view in sectional elevation showing the taping mechanisms;

FIGURE 11 is a fragmentary perspective view of the discharge end of the machine;

FIGURE 12 is an electrical diagram illustrating the electrical mechanism through which the operating instrumentalities of the machine are coordinately controlled and operated;

FIGURE 13 is a fragmentary view in side elevation of a modified measuring section in which side flap folding means are included, and an alternative form of rear flap folder is included;

FIGURE 14 is a view in end elevation of the measuring section of FIGURE 13, looking into the discharge end of the measuring section;

FIGURE 15 is a perspective view of a second practical and advantageous illustrative embodiment of the invention; and

FIGURE 16 is an electrical diagram illustrating the mechanism through which the operating instrumentalities of the machine of FIGURE are coordinately controlled and operated.

In order that a comprehensive preliminary understand- .ing of the illustrative machine of FIGURES I to 12 may be had, the machine will first be described by reference merely to its principal parts and with little attention to detail. In this connection reference will be had principally to FIGURES 1, 2, 3, 4, 10, 11 and 12.

Since the salient novelty of the invention resides in the capability of the machine automatically to accommodate itself to cartons which vary in height and width, the preliminaly description will be directed, except where otherwise stated, to the setting of the machine which provides for automatic accommodation.

The cartons to be taped are brought to the machine on a conventional gravity conveyor 10, a fragment of which is indicated in FIGURE 1 with a single carton 12 supported upon it. Ordinarily there would be a considerable number of cartons upon the conveyor 10, each carton other than the foremost pressing forward against the rear face of the carton which precedes it and the foremost carton pressing forward against a gate GT1. As a rule the cartons enter the first or measuring section of the machine with the front, rear and side flaps extending substantially straight upward.

The machine comprises three successive sections through which the cartons pass. Section 1 is a measuring section, section 2 is a side flap folding section, and section 3 is a taping section. The sections I, 2 and 3 are preceded by gates GTI, GT2 and GT3, respectively, and they include elevators ELI, EL2 and EL3, respectively.

At the beginning of the day, with the power turned off and the machine clear of cartons, the gate GT1 will stand in its raised or closed condition, being spring impelled to that condition. When the main switch, not shown is closed to supply electric power through conductor mains 14 and I6, gates GT1 and GT3 are opened by electromagnets SVI and 5V3. The opening of gate GT1 allows the first carton to enter the measuring section. At

this time, the-elevator ELI will be in its uppermost position, and centering and side-guiding members I8 will be in their outermost positions. Any carton within the capacity of the machine may therefore enter the measuring section and be advanced by a constantly running conveyor to gate GT2.

As the first carton advances through the measuring section to the gate GT2, it closes a switchv 22 and thereby causes a rear flap folder 24 to be swung rearward and upward to a retracted position in which it is clear of the upstanding front and rear end flaps of the carton. The carton next engages and opens the switch 26, causing the electromagnet SVI to be deenergized so that the gate may be urged upward by spring pressure against the overlying carton, and may be caused to return to its upper or closed position as soonas the trailing end of the carton has passed the switch 26.

Just before the carton is arrested by the gate GT2, it closes a switch 28. This causes a height regulating motor MHI to drive the elevator ELI downward until a pivoted feeler arm 30, which is carried by the elevator ELI, is rocked by engagement with the top of the carton into a substantially horizontal position. At this point the downward travel of the motor MHI is arrested through the opening of a switch 32 by the arm 30. Closing of the switch 28 also causes a width adjusting motor MW to drive the guides 18 equally and oppositely inward until two feeler arms 34 carried by and with the guides 18 have both been swung by engagement with the carton sides to circuit breaking positions. If one feeler breaks its circuit branch before the other, the guides will continue inward until the second circuit branch is broken, in the meantime straightening and/ or centering the carton.

As the feeler arm 30 attains its uppermost or horizontal position, it engages and closes a switch 36 through which an electromagnet 5V2 may be energized for opening the gate GT2 and admitting the carton to the second section. Before the carton may be admitted to the second section, however, it is necessary that the elevator of the second section be adjusted to the appropriate level for operating upon the carton which has been measured in the first section and for which the elevator ELI has been correctly adjusted. In series circuit with the switch 36 and the winding SV2, there is provided a switch member 38 which is carried by the elevator EL2 and controlled by a cam 40 on the elevator ELI. The switch 38 has a neutral position in which it open-circuits the winding SV2, but whenever the elevator EL2 is adjusted to correspond to the adjustment of the elevator ELI, the operating arm of the switch will be tilted by a cam 40 to one side or the other of neutral and will be retained in a circuit-closing position. The admission of the carton to the second section is, therefore, made to wait upon the attainment of the correct height adjustment of the elevator EL2.

Height adjustment of the elevator EL2 is eifected by a height adjusting motor MH2 under the primary control of a rockable switch 42. The switch 42 is rockably mounted on the elevator EL2 and is controlled by a divided cam 44 on the elevator ELI. As shown in FIG- URE 12, the elevator EL2 has been properly adjusted relative to the elevator ELI, the switch member 42 stands in its neutral or open condition, and no circuit can be completed through the switch member. Whenever the cam 42 stands at a lower level than that illustrated relative to the switch 42, the switch member 42 will be operated counterclockwise and will make engagement with a conductor 46 through which the motor MH2 may be energized, subject to other controls, for driving the elevator EL2 downward. If, on the other hand, the switch member 42 were located at a lower level than the cam 44 (as it frequently would be in practice) the switch member 42 would be tilted clockwise and would make engagement with a conductor 48 through which the motor MH2 may be energized, subject to other controls, for driving the elevator EL2 upward. Whatever the direction of travel of the elevator EL2, such travel will be arrested uponthe arrival of the switch member 42 at the condition relative to the cam 44 which is illustrated in FIGURE 12.

At the start of the day, with the elevators ELI and EL2 both in their uppermost positions, as shown in FIGURE 12, the downward measuring movement of the elevator ELI will rock the switch member 42 counterclockwise and will cause the elevator EL2 to be driven downward almost in unison with the elevator ELI and to come to rest substantially at the same time that the elevator ELI comes to rest.

Completion of the adjustment of elevator EL2 will reestablish the closed condition of switch 38 as illustrated in FIGURE 12, thereby causing the Winding SV2 to be energized and the gate GT2 to be opened. This permits the carton to advance into the second section. As the carton again moves forward, it opens a switch 58 and thereby deenergizes the electromagnet SV2, causing the gate GT2 to be freed for upward movement under the impulsion of a spring (not shown). The gate GT2 is held down by the overlying carton, but as soon as the trailing end of the carton has cleared the gate, the gate swings upward to its closed position.

At the same time that the carton opens the switch 58, it closes a switch 60, causing the flap closer 24 to be swung forcibly downward and forward against the upstanding rear flap of the carton. This folds the rear flap forward and downward to a horizontal position and causes it to be held in that position as the flap travels forward into engagement with the lower face of the feeler arm 30. While the arm 39 has been referred to as a feeler arm, it is considerably more than that, since it serves also as a folder for the front flap of the carton and as a hold-down for the front flap and then the rear flap as the carton moves forward.

Closing of the switch 60 also causes windings 62 and 64 to be energized for setting switches 65 and 68 in open positions. The opening of the switch 65 prevents operation of the motors MW and Ml-Ill until after the switch 66 has been engaged and reclosed by the leading end of the advancing carton. The switch 66 is so located that the carton will have moved clear of the first section before the upward travel of the motor Mlil and the outward travel of the motor MW can be initiated.

With the reclosing of the switch 66, the elevator ELl will be driven to its upper limit, being brought to rest by the opening of a switch 76, and the guides 18 will be driven to their outer limits, being brought to rest by a limit switch 72. The arrival of the elevator ELK at its upper limit of movement, closes a switch 74 and thereby causes the electromagnet 8V1 to be energized for opening the gate GT1 and admitting another carton to the measuring section. At this time all the operating mechanism of the measuring section is free to respond to the new carton in the manner already described. The downward travel of the elevator ELI is initiated by closing of the switch 25; by the new carton.

The elevator ELZ does not move upward with the elevator EL]. because at this time the switch 68 still stands open, and the closing of switch 68 is a necessary condition precedent to the further operation of the motor MHZ in either direction. This is a necessary safeguard because the elevator ELZ must not be disturbed in position until the irst carton has moved clear of the second sec tion. The switch 68 is located in the third or taping section for engagement by the carton after the carton has cleared the second section. Before the carton can reach the switch 68, however, it must pass the gate GT3, and before the gate GT3 can be opened, the elevator ELS must be adjusted in height to correspond to the adjustment of the elevator ELZ.

The principle of control of the elevator EL3 from the elevator EL2 is the same as that described for the control of the elevator ELZ from the elevator ELI. At the start of the day, however, all sections will be clear, and all elevators will be in their uppermost positions as illustrated in FIGURE 12. Before the elevator ELZ moves downward, a switch member 7 carried by the elevator EL3 stands in its neutral condition embracing a divided cam 76 on the elevator ELZ. As the elevator E112 moves downward, however, the switch member 74 is rocked counterclockwise and is thereby caused to establish connection with a conductor '76 through which the motor MES is driven in a direction to lower the elevator EL3. The elevator EL? moves downward substantially in unison with the elevator EL2 until, at the proper level, the illustrated relation of switch member 74 to cam 76 is reestablished. The reestablishment of this condition also reestablishes the illustrated condition of the switch member 78 carried by elevator EL3 to cam 8t) carried by elevator ELZ. This completes a circuit through 8V3 for opening the gate GT3 and hence the first carton finds the gate GT3 in an open condition.

As the carton moves into and through the third section, it opens a switch 32, and thereby deenergizes the winding 8V3. The gate GT3 is thereby released to press upward'against the overlying carton and to close as soon as it is cleared by the carton. Simultaneously with the closing of the switch 82 by the carton, a switch 84 is closed by the carton. Closing of the switch 84- causes a relay winding 86 to be energized and this in turn opens a switch 83, setting it to an open position and thereby rendering the motor Ml-l3 temporarily inoperable.

As the carton continues its advance through the third section it engages and closes a switch 91d thereby causing a-length of tape, which is longer than the carton itself V justment to a lower level, the switch 74 will stand in a by a predetermined amount to be automatically fed out, moistened and applied to the traveling carton. The tape is cut oil with one end portion of predetermined length protruding beyond the leading end of the carton and another end portion of substantially the same length protruding beyond the trailing end of the carton. The cutting oil of the tape is effected as the carton clears the switch as. The surplus length of the tape is accounted for by the fact that the actuating arm of the switch extends for a substantial distance in he direction of carton travel.

After the carton has cleared the second section, it engages and closes the switch 68 thereby freeing the motor MHZ for operation to adjust the elevator ELZ to the level of the elevator ELI. This may be to the upper limit if no followingv carton has entered the measuringsection and been measured, or it may be to a new position of elevator ELI as determined by a new carton measurement.

The first carton next closes a switch $2 to set into operation a roll-down device 94 whereby the protruding leading end of the tape is rolled down across the leading end of the carton. The roll-down device starts downward in time to intercept momentarily and arrest the carton, but releases the carton for resumed forward movement as it moves upward to a position clear of the carton.

An untimed, continuously operating roll-over mechanism d6, which is disposed a short distance ahead of the roll-down mechanism 94, serves to roll the protruding trailing end of the tape against the rear face of the carton without interrupting the advance of the carton.

The carton finally engages and closes a switch 88, thereby freeing the motor Nil-l3 for operation to adjust the elevator EL? into correspondence with the elevator ELZ. The second carton may, of course, be either of greater or less height than the first carton. When the second carton is of greater height than the first and the elevator ELZ has been adjusted to the height of the second carton but the elevator ELS has not, the switch member 74 will stand in a position to make connection with a conductor 1&2 through which the motor MH3 is caused to drive the elevator EL3 upward.

When, on the contrary, the elevator EL3 requires ad tilted position to make connection with a conductor 76 through which the motor MH 3 is energized to drive the elevator EL3 downward.

The machine of FIGURES l to 12, when operated as above described, is a very practical and satisfactory machine. It is unique in its capability for automatically taping cartons which continually vary in height and width. With the delays for measurement, however, it is necessarily limited in its rate of output as compared with a conventional machine which operates on cartons of uniform dimensions only, and through which the cartons are advanced without interruptions. It is a feature of the invention that a mere flip of a switch is required in order to convert the machine of FIGURES 1 to 12 into a machine of the latter class.

It will be observed that the conductor mains M and 16 are connected, respectively, with principal branch conductors Ma and 16a and with secondary branch conductors 14b and 16b. The conductors 14b and 16b may be connected through two-position switches res and 108, respectively, with conductors 14c and 160. The switches 106 and M8 are desirably connected for operation by a common operator 11th. When the machine is set for automatic adjustment, as above described, the switch member 106 is maintained in conductive engagement with conductor 14c, and the switch 1% is maintained open, but when the machine is set for continuously putting through cartons of uniform heights and widths, the operator 110 is actuated to reverse the conditions of these switchesthat is to say, to swing the switch lltlfi out of conductive engagement with the conductor 14c and to swing the switch spawn 108 into conductive engagement with the conductor 160.

In the setting for automatic adjustment, conductors 110, 112 and 114 are live at all times, being connected through 14c and 14b to conductor 14. The live conditions of the conductors 110, 112 and 114 are essential, respectively, to the operability of the motors MHI and MW, MHZ, and MH3. When the switch 106 is opened, therefore, the motors MW, MHI, MHZ and MH3 are disabled, with the consequence that the side guides 18 and the elevators EL1, EL2 and EL3 are caused to hold the positions in which they are set at the instant of switch opening Operation of the switch 106 to open-circuit conductor 14c, establishes a fixed connection from 14b through the switch 166 and conductors 116 and 118 to the winding SVZ. In the setting for automatic adjustment, the switch 1.08 stands open and thereby renders the conductor 16c and its branch conductors 16c1, 16c2 and 16c3 ineffective to complete any circuit. The closing of switch 168, however, causes the conductors 16c1, 1602 and 1603 to establish and maintain uninterrupted connection of the windings 5V1, SV2 and 8V3, respectively, with the conductor 16. The winding SVl, SV2 and SV3 are therefore continuously energized, and the gates GT1, GT2 and GT3 are continuously held open.

As an alternative to the provision of conductor 116, the feeler 39 might be arranged to be electromagnetically detained, under control of the operator 116 at its upper limit of movement, so as to hold the switch 36 continuoutsly closed and thereby maintain energization of the winding SV2. As a further alternative, the conductor 116 may be omitted and the arm 30 may be left free to drop down between cartons since the switch 36 will always be closed by the carton engaged feeler arm 30 by the time the carton reaches the gate GT2 and will cause the gate GT2 invariably to be opened in time to avoid the arresting of the'carton.

Before shifting the operator 110 to open-circuit conductor 14c and to connect in circuit the conductor 160, the person in charge of the machine would briefly hold back the leading one of the uniform cartons on the conveyor long enough to let any carton or cartons in the machine pass out of the machine. He would then release the carton which he has been holding to let it enter the measuring section and would thereafter actuate the operator 110 to throw the switches after the leading end of the carton had passed the gate GT2 and before it had reached the switch 66. At this time the elevators would all be adjusted to the proper, common level and the guides 18 would be adjusted to the proper width. As the leading carton enters the measuring section, it pulls away from the next following carton, leaving a space into which gate GT1 can enter as the leading carton clears the gate.

When it is desired to switch back to automatic adjustment, the first of the irregular cartons would be held back until the last of the uniform cartons had cleared the machine, and the operator 110 would then be actuated to switch in conductor 14c and switch out conductor 160. The operator would then release the carton which he has been holding back, and the automatic operation would proceed as described in connection with the start of a days operations.

The introductory conveyor 10 has its own rigid frame 120. While this conveyor has been described as a gravity conveyor it could, of course, be driven throughout its length at a relatively slow speed, or be made to include one or more rollers at its discharge end which are driven at a relatively slow constant speed. The machine itself is fully operative in conjunction with any kind of conveyor which yieldingly advances the cartons at a substantially slower speed than the speed of the conveyor 20. The difference of speed is important primarily because the leading carton, when admitted to the machine by gate GT1, should pull away from the following car- 8 ton, leaving a space into which the gate GT1 may enter as soon as the leading carton has cleared the gate.

The machine proper includes a frame which, though unitary and rigid in the final assembly, may be built in sections for convenience in loading, unloading, shipping and installation of the machine itself. The frame is composed of tall upright channel bars 122 at opposite sides of the machine, longitudinal bars 124, 126 and 128, and transverse bars 130, 132 and 134. At the introductory end, longitudinal bars 126 extend well beyond the terminal uprights 122. At the discharge end longitudinal bars 124 and 126 extend well beyond the terminal uprights 122 and are connected with shorter upright channel bars 136.

The frame portion of section 1 is supplemented at the top by a frame superstructure which comprises members 138 for supporting the motor MHI and mechanism operated by the motor. The structure is duplicated for the other sections so that a description of section 1 will suffice for all, and like reference characters have been applied in all sections. The motor MHl is connected through suitable gearing (not shown) to drive four endless chains 140. The chains run upon, and depend from, sprockets (not shown), which sprockets are revolubly mounted at opposite ends of each side of the frame on the bars 128.

Two arms 142 extend downward from the elevator ELI and provide pivotal support for the feeler arm 30. The arm 30 is biased toward the position in which it is illustrated in FIG. 6 by a tension spring 144', being limited to the position shown by a stop arm 146 which is mounted on one of the arms 142. The arm 30 is rocked clockwise, as viewed in FIG. 6, by engagement with the front flap at the top of a carton as the elevator ELI moves downward. The arm is provided with switch actuating projections 143 and 150 for cooperating, respectively, with normally closed switch 32 and normally open switch 36. The switches 32 and 36 are carried on a bracket 152 which is fixed upon the elevator ELI.

The anchor shaped rear flap closer 24 is fast on a shaft 154, which shaft extends transversely of the machine and is supported in bearing arms 156 of the elevator EL1. A shelf 157 of the elevator ELI supports a pneumatic actuator 158 for the rear flap closer 24. The actuator 158 is a familiar commercial device, being exemplified by the Bellows Air Motor as made by the Bellows Company of Akron, Ohio. The actuator 158 is that type of air motor in which energization of one solenoid winding 160 sets a valve (not shown) to cause air under pressure to be admitted to one end of a cylinder 162 and to permit air to be discharged from the second end, while energization of another solenoid winding 164 resets the valve to cause air under pressure to be admitted to the second end of the cylinder and to permit air to be discharged from the first end. The air motor includes a piston (not shown) and a rigid piston rod which terminates in a rack 166. The rack 166 is constantly in mesh with a pinion 168 which is fast on the shaft 154. Energization of the solenoid 160 through closing of the switch 22, drives the rack 166 outward from the cylinder and swings the flap closer counterclockwise as viewed in FIG. 6, to the full line position in which it is shown in that figure. Subsequent energization of the winding 164 through closing of the switch 60, drives the rack 166 inward relative to the cylinder and swings the flap closer clockwise as viewed in FIG. 6, to the broken line position in which it is shown in that figure.

The conveyor 20 comprises a multiplicity of identical rollers 172. A drive motor 173 is connected through a chain drive 174 to drive a slow speed roller 175, which precedes the conveyor, continuously and at uniform speed. The shaft of roller 175 is connected through chain gearing which includes large and small sprockets 177 and 179 to drive the first roller 172 of the conveyor at cons amans siderably faster rotary and peripheral speeds than the corresponding speeds of the roller 175. The roller 175 serves, when the machine is set for non-measuring operation, to hold back each carton relative to its predecessor long enough to provide a desirable spacing between cartons. Each roller 172, other than the extreme rollers of the series, is connected to one of its neighbors through an inner drive chain 176 and to another of its neighbors through an outer drive chain 178. All the rollers, therefore, turn at the same peripheral speed and tend to advance the cartons at a uniform speed.

The side guides 18 are made fast at their opposite ends upon racks 130, the racks being connected for equal, simultaneous operation to adjust the side guides in and out while maintaining them in parallelism with the longitudinal center line of the machine. The motor is supported beneath the conveyor 20 from a beam 132, and has an output shaft 184 whose ends extend outward from the motor toward the opposite sides of the machine. The shaft 184 is connected to drive vertical shafts Tue-through gearing (not shown), the latter shafts, in turn, being connected to drive shafts 188 and 1% in opposite directions. The shafts 188 and 1% have fast upon them gears (not shown) for engaging and driving the guide carrying racks 180 coordinately. Coordination in this context requires that the side guides be driven inward simultaneously and to equal extents and that they be driven outward simultaneously and to equal extents, and this is the kind of operation which is produced by the described mechanism.

Details of the mounting and control means for the side guides may be seen in FIG. 7. The mechanism here illustrated is provided in duplicate at opposite sides of the machine. Gear boxes 192 are supported from frame members 122 through brackets 194. Each rack 11% extends through one of the gear boxes and is attached to a side guide 18 near one end thereof. Each side guide 18 carries a bracket 196 upon which one of the feeler arms 34 is pivoted for inward and outward swinging movement. Each arm is provided with a stop arm 193 which extends over, and normally bears against an outer face of, the associated side guide 18. The housing of a switch 200 is secured upon each bracket 196. The switch housing includes a sleeve 202 and an actuator stem 2494, both of which extend toward the. feeler 34. A compression coil spring 206 surrounds the sleeve 202 and the actuator stem 204 and bears at its opposite end against the feeler 34 and the housing of the switch 209, respectively. The spring urges the feeler counterclockwise (as viewed in FIG. 7) maintaining it, in the absence of a carton, in the position illustrated. In this position the actuator 204 is not engaged by the feeler 34 and the normally closed switch 200 remains closed.

The elevator EL2 comprises side bars 2% and cross plates 208 and 210. Folding belts 212 run at their forward ends upon comparatively large diameter, horizontally disposed pulleys 214 and at their rear ends upon comparatively small diameter, vertically disposed pulleys 216. The forward pulleys 214 are carried upon drive shafts 218 and 220, respectively, which are supported from the plate 210 in depending brackets 222. The shafts 218 and 220 are connected to one another through a universal joint 224 as that the latter shaft is driven from the former. The pulleys 216 are disposed out near the side bars 266, being supported in brackets 226, whereas the pulleys 214 are disposed well in from the side bars 2% so that the lower, active runs of the pulleys 212 converge as they travel forward from the pulleys 216 to the pulleys 214.

The shafts 218, on which one of the pulleys 214'is made fast, is driven by a motor 228 which is supported from the crossplate 208 upon a platformbracket 230. The motor shaft 232, through chain gearing 234, drives gearing (not shown) which is located within a gear box 236. The gear box 236 is mounted on the bracket 23%. The gearing in the box 236 is connected through chain gearing if 238 to drive the shaft 218. The motor 228 is driven at constant speed.

The twisted active runs of the belts 212 exert both a carnming and a wiping action upon the side flaps, turning them inward and downward and pressing them firmly down against the underlying front and rear flaps of the carton. The belts 212 start from far enough out to accept between them the upstanding side flaps of the widest carton within the range of the machine, but extend inward far enough effectively to fold in the side flaps of the narrowest carton within the range of the machine. The belts 212 are carried up and down with the elevator EL2, but require no lateral adjustment,

The side guides 18 extend only through the measuring section, but since the cartons overlap the measuring section and the side flap folding section during a considerable part of the side flap folding operation, the side guides contribute importantly to the resistance of the carton to misalignment or lateral displacement by forces exerted upon it by the belts 212. The conveyor 24% of the folding section is adapted also to resist later-a1 displacement and misalignment of the carton, being in the form of a belt conveyor. The conveyor 2% comprises a broad belt 242 of frictional material, a driven end drum 244, an idler end drum 246, and an intervening roller table composed of closely spaced idler rollers 248 upon which the active run of the belt 242 is supported. The drum 244 is desirably driven independently of the conveyor 2%, but at substantially the same speed, by an independent motor 250. It is not essential that the speeds of the conveyors 20 and 24% be identical.

As the folding in of the side flaps by the belts 212 is completed, the carton stands ready to pass from the belt conveyor 240 onto a conveyor 252 of the taping section, as soon as the taping section is ready to receive it. This means, of course, that the elevator EL3 must have been adjusted to the appropriate height by reference to the position of the elevtor EL2 and the gate GT3 must be open. Under these conditions the carton passes forward onto a conveyor 252 and beneath a holddown roller conveyor 252a which is carried by the elevator EL3. Shortly after entering the taping section, the carton engages and closes switch for causing tape to be fed, moistened, cut and applied both by the overhead mechanism which seals the top center seam of the carton and by underneath mechanism which seals the bottom center seam of the carton.

The rollers 254 of the lower roller conveyor 252 are driven in unison and at constant speed from the motor 259 which is suspended from the frame beneath the conveyor 252, and which is connected through gearing indicated at 256 to drive an intermediate roller 254 of the conveyor 252. The shaft of said roller 254, through a system of chains and sprockets 253 drives all the rollers 254 in unison with itself. The end roller 254 which lies nearest the drum 244 is connected through chain gearing 257 to drive the drum 244.

The general arrangement is similar for the conveyor 252a which is carried by the elevator EL3. A motor 25%, carried by the elevator EL3, serves to drive one roller of the conveyor 252a, and the shaft of that roller serves to drive all the other rollers in unison with itself and in harmony with the rollers of the conveyor 252. Not only are the conveyors 252 and 252a duplicates of one another, but the tape feeding, m-oistening, cutting and applying means of the upper mechanism are essentially duplicates of the corresponding elements of the lower mechanism. The lower mechanism only will be described, and corresponding reference characters will be applied to corresponding parts of the upper mechanism with the subscript a added in each instance.

One of the rollers 254 has its shaft connected through gearing (not shown) to drive the lower tape. feeding means. Such gearing constantly drives rollers 264, 266 and 263 at a peripheral speed equal to the peripheral speed of the rollers 254. The tape feed drive is not 11 completely illustrated in detail, the construction and arrangement being well-known and being as shown and described in United States Letters Patent 2,721,669, granted to Clifford D. Keely on October 25, 1955. The tape T is drawn from a reel 260.

The tape moistening means and the means for causing the tape to be alternately fed and cut are also like the corresponding parts of Patent 2,721,669.

The tape feeding begins as soon as the switch actuating arm 90 is engaged and depressed by the leading end of a carton and continues at the rate of carton travel until the arm 9t) is cleared by the trailing end of the carton. The length of tape fed is equal substantially to the length of the carton plus the length of the switch actuator arm 90. The arm 90 is so situated that the surplus tape length is divided substantially equally between front and rear protruding end portions.

The lowermost of the constantly driven rollers 266 is a tape moistening roller. It runs in contact with a water pick-up roller 270. The roller 27%) runs in water 272, which water is supplied to a tank 274 from a supply pipe 276 and is maintained automatically at a desired level by a float valve 278.

The armature 280 of a solenoid 282 is arranged, when the solenoid is energized, to thrust downward a lever 284. The lever 284 is pivotally mounted on a fulcrum pin 286. The lever 284 carries on one arm an idler roller 288 which is moved toward and from the constantly driven roller 264 as the solenoid is energized and deenergized, respectively and on the other arm a pinch cutting blade 290 which is moved toward and from a non-driven anvil roller 292 as the solenoid is deenergized and energized, respectiveley. As the solenoid circuit is broken, by opening of the switch 90, causing the solenoid 282 to be deenergized, the roller 288 is moved away from the roller 264 and the blade 290 is snapped into engagement with the anvil roller 292 by a spring 294 to cut the tape. The cut length of tape continues to be fed until it has all been delivered to the carton, but the uncut tape below the knife 290 remains at rest until another carton comes along to energize the solenoid 282.

The shaft 296 of the final roller 254 of the conveyor 252 serves through chain and sprocket gearing 298 to drive the shaft 306 of the lower roll-over device 96 through a slip clutch driver 301. The carrier 302 of the rollers 30-4 is mounted on the shaft 300 for rotation in unison therewith. The carrier 302 comprises arms 306 which are located at opposite sides of an idler roller 308. The upper roll-over mechanism 96a is a duplicate of the lower roll-over mechanism and is similarly driven.

A sub-frame 310, fixed on the elevator EL3 serves as the support and carrier for the upper roll-over mechanism 36a and the upper roll-down mechanism 94a.

A plungerhead 312a includes a rigid, vertically extending guide bar 314a which is guided for vertical restriction to vertical movement in a guideway provided by an extension 31% of elevator EL3. The plunger head 312a is carried at the lower end of the piston rod of an air motor 316a, and is driven down and up by the piston rod. The plunger head 312a has pivoted upon it at 318a a bearing frame 320a for "the roll-down roller 322a. The bearing frame 326a includes a pair of parallel angle levers 324a which are connected by a cross bar 326a. A compres sion coil spring 328a interposed between the plunger head 312a and the crossbar 326a yieldingly urges the frame 320a in a counterclockwise direction (as viewed in FIG. 11). Such movement is limited by engagement of projections 330a of the levers 324a with abutment stops 332a on the plunger head 312a. The spring 328a permits a slight yielding in a forward and upward direction of the bearing frame 356a. V

The upper roll-down mechanism has been described in detail rather than the lower one because it is more fully illustrated.- The upper and lower mechanisms 96a and 96 are desirably duplicates of one another. Correspond- 12 ing parts of the lower mechanism, to the extent that it is illustrated, have corresponding reference characters applied with the subscript a omitted in each instance.

There is a minor point of differentiation between the drive gearing 334 for the lower roll-over mechanism 96 and the drive mechanism 334a for the upper roll-over mechanism 96a, arising from the fact that lower conveyors are associated with the lower roll-over mechanism 96, whereas no conveyor is associated with the upper mechanism 96a. As seen in FIG. 11 the upper drive gearconsists merely of sprockets mounted on the shafts 336a and 338a and an intervening chain. The lower drive gearing, however, consists of a first pair of sprockets 340 and 342 on shafts 336 and 344 with a chain 346 running on the sprockets, and a second pair of sprockets and 350 on the shafts 344 and 338 with a chain 352 running on the sprockets. The shaft 344, as seen in FIG. 11, drives a roller 354 which constitutes the drive roller of a conveyor belt 356. At the opposite side of the machine (see FIG. 3), the shaft 336 serves through a second set of sprockets 340 and 348 and a second chain 346 to drive a second shaft 344, and through the latter to drive a second roller 354 by which a second conveyor belt 356 is driven. The conveyor belts 356 run also upon idler rollers 358 at their discharge ends and upon series of idler rollers 360 intermediate their ends. Intermediate frame members 362 are provided for supporting the rollers 354, 358 and 360 at their inner ends.

Further details of the upper roll-down mechanism are illustrated in FIG. 8, having reference particularly to the control of the switch 92 through which a solenoid winding 364a is energized for setting the roll-down actuator into operation. a Bellows air motor of the type in which solenoid energization shifts the air valve to produce a complete automatic cycle of the piston. When the switch actuator arm 92 is engaged by the carton, it is rocked in a counterclockwise direction about a supporting pivot pin 366a, and causes a pawl carrying arm 368a to be rocked counterclockwise with it. A pawl 370a carried by the arm 368a advances a ratchet wheel 372a a single step, causing one tooth of the ratchet wheel to be fed past an anti-lback-feed pawl 374a. As the anti-back-feed pawl 374a rides over the passing tooth it momentarily closes the switch 92 and then permits the switch to re-open. The momentary closing of the switch 92 sufiices, however, to initiate a full cycle of the roll-down mechanism. The initiation of the roll-down cycle is started early enough so that the roll-down roller 322a will have moved down across the leading end of the carton as the carton approaches the roll-down station, far enough to intercept and arrest the carton for a short time at that station. As the roller 322a continues downward it rolls the leading protruding end of the tape smoothly and firmly down against the leading end of the carton, and it again presses the leading end of the tape against the carton as it returns upward. As soon as the upwardly moving roller 322a clears the carton, the forward feeding of the carton is resumed, and the carton is carried past the switch 88 and out of the machine, desirably onto a further gravity conveyor (not shown).

In FIGURES l3 and 14 disclosure is made of a modified first section which includes side flap folding means, and which is therefore substitutable for the first and sec- 0nd sections of the machine of FIGS. 1 to 12. Besides adding side flap folders, FIGS. 13 and 14 include an alternative form. of rear flap folder. The features particularly illustrated in FIGS. 13 and 14 may be used together or separately.

The structure of FIGS. 13 and 14 is generally like that of the measuring section of FIGS. 1 to 12, including all the structure of those figures except as noted below. Corresponding reference characters have accordingly been applied to corresponding parts in FIGS. 13 and 14 with the subscript d added in each instance, and the description will be confined to the mechanisms which have been In this instance the actuator is 

